Morphology of connective tissue in skeletal muscle

The arrangement and distribution of connective tissue in six different skeletal muscles and smooth muscle was examined by scanning electron microscopy. The endomysial arrangement of collagen was similar in all types of muscle and consisted of three components: (1) myocyte-myocyte connectives; (2) myocyte-capillary connectives; and (3) a weave network of collagen intimately associated with the basal laminae of the myocytes. The perimysium of the different muscles was qualitatively similar but quantitatively dissimilar. The perimysium consisted of large tendon-like bundles of interwoven collagen which connected with the dense weave collagen that surrounded groups of muscles. The arrangement of the collagen in the perimysium and endomysium would explain differences in the mechanical properties of the different muscle. The contribution of the connective tissue to mechanical properties of muscle is discussed.     

Developmental expression of extracellular matrix components in intramuscular connective tissue of bovine semitendinosus muscle

 We have investigated the expression patterns of extracellular matrix components in intramuscular connective tissue during the development of bovine semitendinosus muscle by means of indirect immunofluorescence techniques. Types I, III, V, and VI collagen and fibronectin were located in the endomysium and the perimysium. Type IV collagen, laminin, and heparan sulfate proteoglycans (PGs) were exclusively located in the endomysium, and dermatan sulfate PGs existed only in the perimysium. The localization of these components in the intramuscular connective tissue of semitendinosus muscle remained unchanged throughout prenatal and postnatal growth of cattle, suggesting that they are essential for forming and maintaining structures of the endomysium and perimysium in bovine semitendinosus muscle. On the other hand, decorin was undetectable in the endomysium of neonates, although other matrix components were already expressed. It was expressed slightly in the endomysium of 2-month-old calves, and clearly detectable in the endomysium of cattle more than 6 months old. Chondroitin sulfate PGs were barely detectable in the perimysium of fetuses and neonatal calves, and progressively appeared during postnatal development of the muscle. It seems likely that these PGs are closely related to the postnatal development of the endomysium and perimysium. Accepted: 30 October 1996     

Histological features of endomysium,perimysium and epimysium in rat lateral pterygoid muscle

The distribution of the endomysium, perimysium, and epimysium and their constituent connective tissue fiber types in the mature rat lateral pterygoid muscle was examined with the light microscope. The endomysium and perimysium were relatively thin and consisted mainly of reticular fibers. The epimysium was thicker than the intramuscular sheaths and consisted of both collagen and reticular fibers; however, the thickness and constituent connective tissue fiber types of these sheaths varied regionally. Near the articular capsule and disc, the endomysium, perimysium, and epimysium were all thicker than in other regions of the muscle and consisted of collagen, reticular, and elastic fibers. The perimysium bound the bundles of muscle fibers together and frequently included blood vessels and nerves. As the superior head of the pterygoid muscle approached its insertion, sheaths of perimysium divided this head into smaller and smaller bundles of muscle fibers. In the inferior head, some of the perimysial sheaths and part of the epimysium were aponeurotic, and many muscle fibers attached to them. There were few such aponeurotic regions in the superior head. © 1996 Wiley-Liss, Inc.     

Functional morphology of the endomysium in series fibered muscles.

Many skeletal muscles, including the feline biceps femoris, are composed of short, tapered myofibers arranged in an overlapping longitudinal series. The endomysium of such muscles transfers tension between overlapping myofibers, and is thus an elastic element in series with them. The endomysium of the cat biceps femoris contains curvilinear collagen fibrils in an approximately isotropic (random) array. The collagen fibrils undergo only a modest reorientation as the myofibers shorten or lengthen within the physiological range. A geometrical model predicts no change in the thickness of the endomysium on changing muscle fiber length and quantifies the expected collagen fibril reorientation in the endomysium as a function of muscle extension. It is also demonstrated that a high proportion of the collagen fibrils will be curvilinear at all sarcomere lengths. The organization of endomysial collagen is appropriate for the transfer of loads between myofibers by means of shear.     

Localization of hyaluronan in various muscular tissues

Summary The histochemical distribution of hyaluronan (hyaluronic acid, HYA) was analysed in various types of muscles in the rat by use of a hyaluronan-binding protein (HABP) and the avidin-biotin/peroxidase complex staining procedure. Microwave-aided fixation was used to retain the extracellular location of the glycosaminoglycan. In skeletal muscles, HYA was detected in the connective tissue sheath surrounding the muscles (epimysium), in the septa subdividing the muscle fibre bundles (perimysium) and in the connective tissue surrounding each muscle fibre (endomysium). HYA was heterogeneously distributed in all striated muscles. In skeletal muscles with small fibre dimensions (e.g., the lateral rectus muscle of the eye and the middle ear muscles), HYA was predominantly accumulated around the individual muscle fibres. Perivascular and perineural connective tissue formations were distinctly HYA-positive. In cardiac muscles, HYA was randomly distributed around the branching and interconnecting muscle fibres. In comparison, smooth muscle tissue was devoid of HYA.     

Characterization of muscle epimysium, perimysium and endomysium collagens

In the past it has been proven difficult to separate and characterize collagen from muscle because of its relative paucity in this tissue. The present report presents a comprehensive methodology, combining methods previously described by McCollester [(1962) Biochim. Biophys. Acta 57, 427-437] and Laurent, Cockerill, McAnulty & Hastings [(1981) Anal. Biochem. 113, 301-312], in which the three major tracts of muscle connective tissue, the epimysium, perimysium and endomysium, may be prepared and separated from the bulk of muscle protein. Connective tissue thus prepared may be washed with salt and treated with pepsin to liberate soluble native collagen, or can be washed with sodium dodecyl sulphate to produce a very clean insoluble collagenous product. This latter type of preparation may be used for quantification of the ratio of the major genetic forms of collagen or for measurement of reducible cross-link content to give reproducible results. It was shown that both the epimysium and perimysium contain type I collagen as the major component and type III collagen as a minor component; perimysium also contained traces of type V collagen. The endomysium, the sheaths of individual muscle fibres, was shown to contain both type I and type III collagen as major components. Type V collagen was also present in small amounts, and type IV collagen, the collagenous component of basement membranes, was purified from endomysial preparations. This is the first biochemical demonstration of the presence of type IV collagen in muscle endomysium. The preparation was shown to be very similar to other type IV collagens from other basement membranes on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and was indistinguishable from EHS sarcoma collagen and placenta type IV collagen in the electron microscope after rotary shadowing.     

Immunohistochemical analysis of the distribution of type VI collagen in the lingual mucosa of rats during the morphogenesis of filiform papillae

Iwasaki, S., Yoshizawa, H. and Aoyagi, H. 2012. Immunohistochemical analysis of the distribution of type VI collagen in the lingual mucosa of rats during the morphogenesis of filiform papillae. —Acta Zoologica (Stockholm) 93 : 80–87. We examined the distribution after immunostaining of immunofluorescence of type VI collagen, differential interference contrast (DIC) images, and images obtained using confocal laser‐scanning microscopy in transmission mode, after toluidine blue staining, during morphogenesis of the filiform papillae, keratinization of the lingual epithelium and myogenesis in the rat tongue on semi‐ultrathin sections of epoxy resin‐embedded samples. Immunoreactivity specific for type VI collagen was dispersed over a relatively wide range of connective tissue in the mesenchyme of fetuses on day 15 after conception (E15), at which time the lingual epithelium was composed of one or two layers of cuboidal cells and the lingual muscle was barely recognizable. Slight immunoreactivity specific for type VI collagen was scattered within the lamina propria in fetuses on E17 and on E19, and immunoreactivity was relatively distinct on the connective tissue around the lingual muscle during myogenesis. In fetuses on E19, the epithelium was already stratified squamous. At postnatal stages from P0 to P14, keratinization of the lingual epithelium advanced gradually as morphogenesis of the filiform papillae proceeded during postnatal development. In newborns on P0, myogenesis of the tongue was almost completed. The intensity of immunoreactivity specific for type VI collagen at postnatal stages was mainly restricted on the endomysium and perimysium around the lingual muscle, while scant immunoreactivity was evident in the connective tissue in the lamina propria. Immunoreactivity around the fully mature lingual muscle on P7 and P14 was weaker than that on E19 and P0. Thus, type VI collagen appeared in the connective tissue that surrounded the lingual muscles such as the endomysium and perimysium, in parallel with changes in extracellular components during myogenesis of the tongue.     

Turnover of muscle protein in the fowl. Collagen content and turnover in cardiac and skeletal muscles of the adult fowl and the changes during stretch-induced growth

The collagen content and the rate of collagen synthesis were measured in the anterior and posterior latissimus dorsi muscles and in heart from fully grown fowl. This was done by measuring the proline/hydroxyproline ratios in the muscle and by a constant infusion of [¹⁴C]proline. These measurements were also made during the hypertrophy of the anterior muscle in response to the attachment of a weight to one wing of the fowl. In the non-growing muscles the collagen content was higher in the anterior muscle (22.8% of total protein) than in the posterior muscle (9.5% of total protein) and lowest in the heart (3.8% of total protein). In the two skeletal muscles a little over half of the collagen was accounted for by internal collagen (i.e. perimysium and endomysium). Collagen synthesis in these non-growing muscles occurred at 0.59%/day in each of the two skeletal muscles and at 0.88%/day in the cardiac muscle. During hypertrophy the collagen content of the anterior muscle increased, but not as fast as intracellular protein, so that after 58 days the concentration had fallen from 22.8 to 14.4% of total protein. This may have resulted from an incomplete production of the epimysial sheath, since the concentration of internal collagen did not fall and as a result accounted for over 80% of the total in the enlarged muscle. Collagen synthesis increased 8-fold during the first week of the hypertrophy, but never amounted to more than 4% of the total muscle protein synthesis. When the net accumulation of collagen is compared with the increased rate of synthesis it is concluded that between 30 and 70% of the newly synthesized collagen may have been degraded.     

Location of the integrin complex and extracellular matrix molecules at the chicken myotendinous junction

Summary The distribution of several extracellular matrix macromolecules was investigated at the myotendinous junction of adult chicken gastrocnemius muscle. Localization using monoclonal antibodies specific for 3 basal lamina components (type IV collagen, laminin, and a basement membrane form of heparan sulfate proteoglycan) showed strong fluorescent staining of the myotendinous junction for heparan sulfate proteoglycan and laminin, but not for type IV collagen. In addition, a strong fluorescent stain was observed at the myotendinous junction using a monoclonal antibody against the subunit of the chicken integrin complex (antibody JG 22). Neither fibronectin nor tenascin were concentrated at the myotendinous junction, but instead were present in a fibrillar staining pattern throughout the connective tissue which was closely associated with the myotendinous junction. Tenascin also gave bright fluorescent staining of tendon, but no detectable staining of the perimysium or endomysium. Type I collagen was observed throughout the tendon and in the perimysium, but only faintly in the endomysium. In contrast, type III collagen was present brightly in the endomysium and in the perimysium, but could not be detected in the tendon except when associated with blood vessels and in the epitendineum, which stained intensely. Type VI collagen was found throughout the tendon and in all connective tissue partitions of skeletal muscle. The results indicate that one or more molecules of the integrin family may play an important role in the attachment of muscle to the tendon. This interaction does not appear to involve extensive binding to fibronectin or tenascin, but may involve laminin and heparan sulfate proteoglycan.     

Immunohistochemical localization of genetically distinct types of collagen in muscle of kuruma prawn Penaeus japonicus

• 1.1. The location of genetically distinct types of collagen in muscular tissue of the kuruma prawn was examined using immunohistochemical techniques.
• 2.2. Collagen was distributed not only in muscle connective tissues, which were classified into three forms, epimysium, perimysium and endomysium, but also in subcuticular membrane, which was mainly composed of two layers, hypodermis and subcuticular connective tissue.
• 3.3. The α1(Pr) component existed in all connective tissues in the kuruma prawn muscle. Type AR-II collagen was distributed in all the connective tissues except for the hypodermis, while the α2(Pr) component existed in the thin connective tissues, the perimysium and endomysium, and in the hypodermis.

     

Assessment of cell proliferation and muscular structure following surgical tongue volume reduction in pigs

Objectives: Tongue volume reduction is an adjunct treatment in several orofacial orthopaedic procedures for various craniofacial deformities; it may affect structural reconstitution and functional recovery as a result of the repair process. The aim of this study was to investigate myogenic regeneration and structural alteration of the tongue following surgical tongue volume reduction. Materials and methods: Five 12‐week‐old sibling pairs of Yucatan minipigs (three males and two females) were used. Midline uniform glossectomy was performed on one of each pair (reduction); siblings had identical incisions without tissue removal (sham). All pigs were raised for a further 4 weeks and received 5‐bromo‐2‐deoxyuridine (BrdU) injection intravenously 1 day before killing. Tissue sections of tongues were stained with anti‐BrdU antibody to evaluate numbers of replicating cells. Haematoxylin and eosin plus trichrome staining were performed to assess muscular structure. Results: Reduction tongues contained significantly more BrdU+ cells compared to sham tongues (P < 0.01). However, these BrdU+ cells were mostly identified in reparative connective tissues (fibroblasts) rather than in regenerating muscle tissue (myoblasts). Trichrome‐stained sections showed disorganized collagen fibres linked to few intermittent muscle fibres in the reduction tongues. These myofibres presented signs of atrophy with reduced perimysium and endomysium. Matrix between reduced perimysium and endomysium was filled with fibrous tissue. Conclusions: Fibrosis without predominant myogenic regeneration was the major histological consequence of surgical tongue volume reduction.     

Fibrous framework of human skeletal muscles, fasciae and tendons

By means of scanning and transmissive electron microscopy, the construction of the fibrous framework of the human skeletal muscles, fasciae and tendons has been investigated and its morphofunctional analysis has been performed. The fibrous framework of the endomysium is presented as a complexly organized system of anastomosing fibers of the connective tissue, forming a net-like construction. The fibrous structures of the framework are united into a whole construction by connecting fibers and fibrils. Different types of structural interconnection of collagenous fibers with sarcolemma are revealed. The structure of the fibrous framework both in different muscles and within one muscle has certain peculiarities. The main constructive element of the fascial fibrous framework make large anastomosing collagenous fibers, their architectonics is stabilized by connective fibers and fibrils. The construction of the tendinous fibrous framework is characterized by a pronounced anisotropia of the largest collagenous fibers and a developed network of connective structures both on the surface and inside the collagenous fibers. Structural mechanisms, interconnecting muscles and tendons, are demonstrated. Presence of anastomoses between the fibrils in the composition of the collagenous fibers in the fascia and Achilles tendon are stated. Together with the peculiarities existing, the general principle of the structural organization of the fibrous framework of the muscle system is the net-like constructure dependent on presence of anastomoses and elements of the connective system between the fibrous structures. Depending on the organ's function, the construction of the network acquires certain specific morphological forms.     

Changes in cells's secretory organelles and extracellular matrix during endochondral ossification in the mandibular condyle of the growing rat

The mandibular condyle from 20-day-old rats was examined in the electron microscope with particular attention to intracellular secretory granules and extracellular matrix. Moreover, type II collagen was localized by an immunoperoxidase method. The condyle has been divided into five layers: (1) the most superficial, articular layer, (2) polymorphic cell layer, (3) flattened cell layer, (4) upper hypertrophic, and (5) lower hypertrophic cell layers. In the articular layer, the cells seldom divide, but in the polymorphic layer and upper part of the flattened cell layer, mitosis gives rise to new cells. In these layers, cells produce two types of secretory granules, usually in distinct stacks of the Golgi apparatus; type a, cylindrical granules, in which 300-nm-long threads are packed in bundles which appear "lucent" after formaldehyde fixation; and type b, spherical granules loaded with short, dotted filaments. The matrix is composed of thick banded "lucent" fibrils in a loose feltwork of short, dotted filaments. The cells arising from mitosis undergo endochondral differentiation, which begins in the lower part of the flattened cell layer and is completed in the upper hypertrophic cell layer; it is followed by gradual cell degeneration in the lower hypertrophic cell layer. The cells produce two main types of secretory granules: type b as above; and type c, ovoid granules containing 300-nm-long threads associated with short, dotted filaments. A possibly different secretory granule, type d, dense and cigar-shaped, is also produced. The matrix is composed of thin banded fibrils in a dense feltwork. In the matrix of the superficial layers, the "lucency" of the fibrils indicated that they were composed of collagen I, whereas the "lucency" of the cylindrical secretory granules suggested that they transported collagen I precursors to the matrix. Moreover, the use of ruthenium red indicated that the feltwork was composed of proteoglycan; the dotted filaments packed in spherical granules were similar to, and presumably the source of, the matrix feltwork. The superficial layers did not contain collagen II and were collectively referred to as perichondrium. In the deep layers, the ovoid secretory granules displayed collagen II antigenicity and were likely to transport precursors of this collagen to the matrix, where it appeared in the thin banded fibrils. That these granules also carried proteoglycan to the matrix was suggested by their content of short dotted filaments. Thus the deep layers contained collagen II and proteoglycan as in cartilage; they were collectively referred to as the hyaline cartilage region.     

The dynamics of compartmentalization of embryonic muscle by extracellular matrix molecules

In order to delineate the role of proteoglycans in muscle development, the immunohistological localization of glycosaminoglycans and proteoglycan core proteins was studied in embryonic chick leg at Hamburger-Hamilton stages (St.) 36, 39, 43, and 46, and at 2 weeks posthatching. A specific anatomical landmark was chosen (the junction between the pars pelvica and the pars accessoria of the flexor cruris lateralis muscle) in order to ensure the study of anatomically equivalent sites. Frozen cross sections were immunostained with monoclonal antibodies to chondroitin-4-sulfate, chondroitin-6-sulfate, dermatan sulfate, and keratan sulfate glycosaminoglycans; to the core proteins of muscle/mesenchymal chondroitin sulfate proteoglycan, dermatan sulfate proteoglycan, and basement membrane heparan sulfate proteoglycan; and to laminin and tenascin. Extracellular matrix zones corresponding to the endomysium, perimysium, epimysium, basement membrane, and myotendinous junction each show characteristic immunostaining patterns from St. 36 to St. 46 and have unique matrix compositions by St. 46. In some cases, there is a sequential or coordinate expression of epitopes, first in the epimysium, then the perimysium, and last in the endomysium. Dermatan sulfate proteoglycan is detected in the epimysium at St. 36, in the perimysium at St. 39 (there is no perimysium structure at St. 36), and is not detected in the endomysium until St. 43. A putative mesenchymal proteoglycan core protein (reactive to the monoclonal antibody MY-174) is detected at St. 39 in both epimysium and perimysium, but is not detected in the endomysium until St. 43. Keratan sulfate antibody immunostains epimysium at St. 39 and perimysium at St. 46, but is never detected in the endomysium. Some epitopes are expressed independently in each of the extracellular matrix zones: antibody to tenascin stains only a subset of the epimysium, at the myotendinous junction; and heparan sulfate proteoglycan and laminin are detected only in the endomysium. Between St. 36 and St. 39, the muscle/MY-174-reactive proteoglycan core protein staining decreases in intensity in the endomysium and becomes positive in the epimysium and perimysium. An inverse relationship is found between (1) the disappearance of muscle/MY-174-reactive proteoglycan core protein staining at the surface of myotubes from St. 36 to St. 39 and (2) the infiltration of laminin and heparan sulfate proteoglycan staining encompassing groups of myotubes (St. 36) to circumferential staining of all myotubes (St. 39).(ABSTRACT TRUNCATED AT 400 WORDS)     

Biological resorption of fibers from chitosan in endomysium and perimysium of muscular tissue

The resorption of fibers from chitosan implanted into emdomysium and perimysium of the rat’s broadest muscle of the back is comparatively studied in vivo by the scanning electron microscopy and histologic analysis methods. It is shown that the mechanism and rate of resorption of the fibers from chitosan depend on the fiber localization in the muscular tissue. Implantation of chitosan fibers into endomysium, where they have been in direct contact with muscle fibers, results in 14 days in the formation of transverse cracks, fiber fragmentation, and their partial resorption. Complete resorption of fibers in endomysium is observed in 30 days. Fibers implanted into perimysium maintain integrity in 7 days of the experiment, and a fibrous tissue is formed around the fibers. There is no destruction of chitosan fibers in 45 days of the exposition. The biocompatibility of the chitosan fibers is confirmed by the effective adhesion and proliferation mesenchyme stem cells on their surface.     

Strain-induced reorientation of an intramuscular connective tissue network: implications for passive muscle elasticity

The most abundant intramuscular connective tissue component, the perimysium, of bovine M. sternomandibularis muscle was shown to be a crossed-ply arrangement of crimped collagen fibres which reorientate and decrimp on changing muscle fibre sarcomere length. Reorientation of perimysial strands was observed by light microscopy and identification of these strands as collagen fibres was confirmed by high-angle X-ray diffraction. Mean collagen fibre direction with respect to the muscle fibres ranged from approximately 80 degrees at sarcomere length = 1.1 micron to approximately 20 degrees at 3.9 microns. This behaviour was well described by a model of a crimped planar network surrounding a muscle fibre bundle of constant volume but varying length. Modelling of the mechanical properties of the perimysium at different sarcomere lengths produced a load-sarcomere length curve which was in good agreement with the passive elastic properties of the muscle, especially at long sarcomere lengths. It is concluded that the role of the perimysial collagen network is to prevent over-stretching of the muscle fibre bundles.     

Biochemical and cytochemical characterization of extracellular proteoglycans in the inner circular smooth muscle layer of dog small intestine

Current literature concerning smooth muscle blood vessels has shown versican as the main proteoglycan (PG) component of the matrix. To show whether smooth muscle matrix has the same PG distribution when present in organs, other than the blood vessels, the inner circular smooth muscle layer of the small intestine was obtained by dissection as a highly purified tissue and analyzed by biochemical and cytochemical methods. The smooth muscle layer PGs were extracted from dog small intestine with 4 M guanidine-HCl in the presence of proteinase inhibitors, purified by charge equilibrium, isolated by equilibrium CsCl density gradients, and analyzed in terms of anion exchange, size, and glycosaminoglycan (GAG) distribution. Proteoheparan sulfate itself represented 91.5% of the PGs present in this tissue. The remainder was proteodermatan sulfate. Cytochemical analyses using the cationic dye cuprolinic blue associated with enzymatic treatments with chondroitinases ABC and heparitinase III showed the arrangement and identification of PGs in basal lamina and intramuscular connective tissues. The PGs in the basal lamina were proteoheparan sulfate, and those associated with collagen fibrils in the endomysium and perimysium were rich in dermatan sulfate. In contrast to the blood vessels, inner circular muscle smooth tissue in intestine has, as the main PG, perlecan.     

Fibre type regionalization of forelimb muscles in two mammalian species, Galea musteloides (Rodentia, Caviidae) and Tupaia belangeri (Scandentia, Tupaiidae), with comments on postnatal myogenesis

To investigate structural differences between propulsory and antigravity muscles, the spatial distribution of slow (type I) and fast (type II) muscle fibres in forelimb muscles of two species of small mammals was studied, Galea musteloides and Tupaia belangeri. Serial sections through complete forelimbs were prepared. Following histochemical fibre typing, the forelimbs were reconstructed three-dimensionally using product design software. Most forelimb muscles of both species showed a homogenous distribution of type I fibres. In the supraspinatus and triceps brachii (capita longum et laterale) muscles, however, a segregation of fibre types into ”fast” superficial areas and ”slow” deep regions was observed. Slow regions contained at least 60% type I fibres and were positioned along intramuscular extensions of the tendons of insertion. The functional implications of fibre type regionalization are discussed. An analysis of intramuscular fibre type distribution during postnatal myogenesis revealed no significant differences in muscle fibre differentiation between altricial and precocial juveniles. Differences in locomotor ability probably arise from heterochronic development of connective tissue components (endo- and perimysium). Accepted: 10 June 1999     

Collagen of slow twitch and fast twitch muscle fibres in different types of rat skeletal muscle

The appearance of collagen around individual fast twitch (FT) and slow twitch (ST) muscle fibres was investigated in skeletal muscles with different contractile properties using endurance trained and untrained rats as experimental animals. The collagenous connective tissue was analyzed by measuring hydroxyproline biochemically and by staining collagenous material histochemically in M. soleus (MS), M. rectus femoris (MRF), and M. gastrocnemius (MG). The concentration of hydroxyproline in the ST fibres dissected from MS (2.72 +/- 0.35 micrograms X mg-1 d.w.) was significantly higher than that of the FT fibres dissected from MRF (1.52 +/- 0.33 micrograms X mg-1 d.w.). Similarly, the concentration of hydroxyproline was higher in ST (2.54 +/- 0.51 micrograms X mg-1 d.w.) than in FT fibres (1.60 +/- 0.43 micrograms X mg-1 d.w.), when the fibres were dissected from the same muscle, MG. Histochemical staining of collagenous material agreed with the biochemical evidence that MS and the slow twitch area of MG are more collagenous than MRF and the fast twitch area of MG both at the level of perimysium and endomysium. The variables were not affected by endurance training. When discussing the role of collagen in the function of skeletal muscle it is suggested that the different functional demands of different skeletal muscles are also reflected in the structure of intramuscular connective tissue, even at the level of endomysial collagen. It is supposed that the known differences in the elastic properties of fast tetanic muscle compared to slow tonic muscle as, e.g., the higher compliance of fast muscle could at least partly be explained in terms of the amount, type, and structure of intramuscular collagen.